Provided by: libgle3-dev_3.1.0-7ubuntu2_amd64 
NAME
gleTextureMode - set the type of GLE automatic texture coordinate generation.
SYNTAX
void gleTextureMode (int mode);
ARGUMENTS
mode bitwise OR of GLE texture mode flags
DESCRIPTION
In addition to the default glTexGen modes that are supplied by OpenGL, the tubing library
also contains some of its own automatic texture coordinate generation routines. In
addition, user-defined texture coord generation routines can be supplied.
To use texture mapping with the extrusion library, one must remember to "do the obvious":
Enable texture mapping through OpenGL
Define and load (glTexImage2D/glBindTexture) a texture
If using the routine below, then disable glTexgGen
gleTextureMode can be used to set the type of automatic texture coordinate generation to
be used. The argument should be a bitwise-OR of any of the following flags:
GLE_TEXTURE_ENABLE
If this bit is set, then texturing is enabled. If this bit is NOT set, then
automatic texture coordinate generation is disabled.
The way in which the automatic texture coordinate generation occurs is determined by one
of the following flags. One and only one of these should be selected at a time. These
tokens are enumerants, not bit-flags.
GLE_TEXTURE_VERTEX_FLAT
Uses the vertexes "x" coordinate as the texture "u" coordinate, and the accumulated
segment length as the "v" coordinate.
GLE_TEXTURE_NORMAL_FLAT
Uses the normal vector's "x" coordinate as the texture "u" coordinate, and the
accumulated segment length as the "v" coordinate.
GLE_TEXTURE_VERTEX_CYL
Uses u = phi/(2*pi) = arctan (vy/vx)/(2*pi) as the texture "u" coordinate, and the
accumulated segment length as the "v" coordinate. In the above equation, "vx" and
"vy" stand for the vertex's x and y coordinates.
GLE_TEXTURE_NORMAL_CYL
Uses u = phi/(2*pi) = arctan (ny/nx)/(2*pi) as the texture "u" coordinate, and the
accumulated segment length as the "v" coordinate. In the above equation, "nx" and
"ny" stand for the normal's x and y coordinates.
GLE_TEXTURE_VERTEX_SPH
Uses u = phi/(2*pi) = arctan (vy/vx)/(2*pi) as the texture "u" coordinate, and v =
theta/pi = (1.0 - arccos(vz))/pi as the texture "v" coordinate. In the above
equation, "vx","vy" and "vz" stand for the vertex's x, y and z coordinates.
GLE_TEXTURE_NORMAL_SPH
Uses u = phi/(2*pi) = arctan (ny/nx)/(2*pi) as the texture "u" coordinate, and v =
theta/pi = (1.0 - arccos(nz))/pi as the texture "v" coordinate. In the above
equation, "nx","ny" and "nz" stand for the normal's x, y and z coordinates.
GLE_TEXTURE_VERTEX_MODEL_FLAT
GLE_TEXTURE_NORMAL_MODEL_FLAT
GLE_TEXTURE_VERTEX_MODEL_CYL
GLE_TEXTURE_NORMAL_MODEL_CYL
GLE_TEXTURE_VERTEX_MODEL_SPH
GLE_TEXTURE_NORMAL_MODEL_SPH
These define texture mapping modes that are very similar to those described above,
except that the untransformed vertices and/or normals are used. As a result,
textures tends to stick to the extrusion according to the extrusions local surface
coordinates rather than according to real-space coordinates. This will in general
provide the correct style of texture mapping when affine transforms are being
applied to the contour, since the coordinates used are those prior to the affine
transform.
OPERATION
To best understand how to use the above functions, it is best to understand how the tubing
is actually drawn. Let us start by defining some terms. The tubing library "extrudes" a
"contour" along a "path". The contour is a 2D polyline. The path is a 3D polyline. We use
the word "segment" to refer to a straight-line segment of the path polyline. We also
interchangeably use the word "segment" to stand for the section of the extrusion that lies
along a path segment.
The tubing library draws segments one at a time. It uses glPushmatrix() and glPopmatrix()
to orient each segment along the negative z-axis. The segment starts at z=0 and ends at
some negative z-value (equal to the length of the segment). The segment is then drawn by
calling glVertex3f() (and glNormal3F()) by drawing the 2D contour at z=0 and again at
z=-len. (Of course, if the join style is one of the fancy ones, then the end-points are
trimmed in a variety of ways, and do not land exactly on z=0, or z=-len, but they do come
close). Note that glBegin() and glEnd() are called around each segment. (Note also that
additional glBegins/Ends may be called to draw end-caps or filleting triangles for the
more complex join styles.)
The obvious way to automatically generate textures is to warp the glVertex() and
glNormal() functions, and compute texture coordinates based on the 3-space vertex and
normal coordinates. This is essentially what the tubing code does, except that it passes
some extra parameters. The glBegin calls are wrapped, and the integer segment number and
the floating-point length of the segment are passed in. By knowing the segment number, and
the segment length, the texture coordinates can be adjusted. Knowing the length allows the
length to be accumulated, so that a texture is applied lengthwise along the extrusion. It
is this accumulated length that is used in the FLAT and CYL mapping modes.
For each vertex, not only are the vertex x,y,z coordinates available, but so is a contour
vertex counter indicating which contour vertex this corresponds to. There is also a flag
indicating whether the vertex corresponds to a front or back vertex (i.e. a z=0 or z=-len
vertex). Again, this info can be used to avoid confusion when drawing the more complex
join styles.
HINTS
Here are a few hints, tips, and techniques:
o Hint: Confused? RUN THE DEMOS! The best way to understand what all the different
texture modes are doing is to see them in action.
o Hint: The texture matrix can be used to your advantage! That is, you can use
glMatrixMode(GL_TEXTURE) to control how textures are mapped to the surface. In
particular, you may/will want to use it to to rescale the V coordinate.
o The origin of the contour will in general change the vertex x's and y's, thus
changing the texture coordinates.
o The contour "up" vector will NOT influence the texture coordinates.
o For the FLAT and CYL modes, the accumulated length really is the accumulated length
of the segments in modeling coordinates. Unless the extrusion is very small, this
length will probably be much larger than 1.0, and so the resulting texture
coordinate will wrap. You will generally want to rescale the "V" coordinate to make
the texture map fit.
o If the texture is "swimming" around on the surface in an undesired way, try using
the "MODEL" version of the texture generation flag.
o Typically, you will NOT want to use the "SPH" versions of the texture generation
engine unless you really, really have an extrusion for which spherical coordinates
are appropriate. Most uses of extrusions are best handled with the "FLAT" and "CYL"
generation methods.
o User-defined texture generation callbacks are not currently implemented, but these
should be very, very easy to hack in as desired. It should be easy to let your
imagination run wild in here. Look at texgen.c -- what needs to be done should be
obvious, I hope. When in doubt, experiment.
BUGS
Multiple threads using GLE share a single texture mode.
SEE ALSO
gleExtrusion, gleSetJoinStyle
AUTHOR
Linas Vepstas (linas@linas.org)